Blind process and receiver to determine space-time parameters of a propagation channel

ABSTRACT

Blind or partially blind process to determine characteristic space-time parameters of a propagation channel in a system comprising at least one reception sensor receiving a signal y(t). It comprises at least one step in which the specular type structure of the channel is used and a step for the joint determination of parameters such as antenna vectors (a) and/or time vectors (τ) starting from second order statistics of the received signals.  
     Application for monitoring the spectrum of a propagation channel for positioning purposes starting from one or several HF stations or for standard communication links with equalization or positioning or spatial filtering.

FIELD OF THE INVENTION

[0001] This invention relates to a process and a receiver for blind identification of characteristic parameters of a propagation channel, particularly from second order statistics of the signal received by a sensor.

[0002] For example, the identified parameters are the delay and attenuation of channel paths.

[0003] The invention is particularly applicable in the field of mobile radiocommunications or ionospheric HF links.

BACKGROUND

[0004] Specular Channel

[0005] HF mobile or ionospheric radiocommunications are affected by the multiple path phenomenon. In urban areas, the transmitted signal is reflected and diffracted on fixed or moving obstacles present in the environment. For HF transmissions, the reflections are made on different layers of the ionosphere. In the case of propagation channels that can be qualified as specular, in other words the transmission takes place along a limited number of discrete or temporary paths characterized by a delay and a complex attenuation. Assuming an observation time compatible with the stationarity duration of the channel, multi-sensor reception and specular propagation, the expression for the multi-sensor channel is: $\begin{matrix} {{c(t)} = {\sum\limits_{k = 1}^{d}\quad {a_{k}{\delta \left( {t - \tau_{k}} \right)}}}} & (1) \end{matrix}$

[0006] where k is the index of a path, a_(k) is the vector for which the components are complex attenuations of the path k for the different channels, τ_(k) is the delay associated with the kth path and cl is the number of paths in a channel.

[0007] Furthermore, if each path k is incident on the network following a reduced spatial diffusion cone, the expression (1) is in the following form $\begin{matrix} {{c(t)} = {\sum\limits_{k = 1}^{d}\quad {\beta_{k}{a\left( \theta_{k} \right)}{\delta \left( {t - \tau_{k}} \right)}}}} & (2) \end{matrix}$

[0008] where a(θ_(k)) is the input vector for an angle associated with the kth path and β_(k) is the complex attenuation of the path.

[0009] In the first case (Eq. 1), the channel is not defined by parameters related to the direction from which the paths arrive, each propagation path is defined by parameters consisting of an arrival time τ and an <<antenna vector >> a. Thus, the calibration is no longer necessary and algorithms are no longer limited by spatial dispersion or coherent paths.

[0010] In the second case (Eq. 2), paths are defined by parameters consisting of their directions of arrival, which assumes that the type of the antenna is known and therefore generally involves setting up a calibration to estimate the values of θ_(k).

[0011] Blind Identification

[0012] In active or driven systems, the channel parameters are calculated during a learning phase in which the transmitter transmits a sequence known to the receiver.

[0013] If the propagation channel fluctuates in time, particularly due to movements of mobile stations or ionospheric layers, the sequence must be sent periodically in order to update the value of the parameters.

[0014] If this type of system is efficient, the regular transmission of a learning sequence can cause a significant reduction in the effective throughput.

[0015] For example, in the STANAG 4285 standard for cooperative ionospheric HF transmissions, half of the transmitted symbols are learning symbols.

[0016] Prior art also includes different blind methods and systems, in which parameters are estimated starting from statistics of the received signal, without any advance knowledge of the learning sequence.

[0017] Second Order Techniques

[0018] For example, the proposed techniques simply use second order statistics (space-time covariance matrix) of the received signal. Second order algorithms have better convergence properties than higher order algorithms, i.e. the variance of second order estimators for a given number of symbols, is usually less than the variance of estimators with higher orders. Furthermore, they have fewer local optimisation problems than techniques with higher orders.

[0019] Various methods and algorithms have been developed, such as those described in document entitled “Multichannel Blind Identification : from subspace to maximum likelihood methods” by L. Tong and S. Perreau; Proceedings of the IEEE, 86(10): 1951-1967, October 1998. One of the disadvantages of these algorithms is that the length of the global transmission channel has to be known, and most of them are intolerant to an error in the estimate of this length. When the bandwidth of the transmission is limited, the channel length is only defined approximately and these algorithms can no longer be used.

[0020] State of the Art for Blind Parametric Identification

[0021] Most work on blind identification of characteristic propagation parameters uses decoupled algorithms, i.e. algorithms that independently estimate arrival times and antenna vectors or arrival directions. These include direction finding algorithms to estimate directions of arrival, and coherent source separation algorithms to estimate antenna vectors. A lot of work has also be done on estimating arrival times.

[0022] Joint estimating methods can improve the precision and resolution of estimators, such that parameters can be estimated even when delays (or angles) are very similar.

[0023] The main work done on blind joint estimating of parameters (θ,τ) is described in the following references:

[0024] “Identification spatio-temporelle de canaux de propagation à trajets multiples” (“Space-time identification of multipath propagation channels) by J. Gouffraud, PhD thesis, Ecole Normale Supérieure de Cachan, 1997, and

[0025] “Improved blind channel identification using a parametric approach” by M. C. Vanderveen and A. Paulraj, IEEE Communications Letters, pages 226-228, August 1998.

[0026] The idea is that criteria used to make a blind estimate of the pulse response may be directly minimized as a function of the angles and delays, using subspace type criteria like those described in the “Subspace methods for the blind identification of multichannel FIR filters” paper by E. Moulines, P. Duhamel, J-F. Cardoso and S. Mayrargue, IEEE Trans. on signal Processing, 43(2): 516-525, February 1995. These algorithms require that the transmission/reception filter is known in advance and that the antenna is calibrated.

[0027] Furthermore, an example of a method of making a joint blind estimate of parameters (a,τ) is described in the “Methods for blind equalization and resolution of overlapping echoes of unknown shape” paper by A. Swindlehurst and J. Gunther, IEEE Trans. on Signal Processing, 47(5): 1245-1254, May 1999. The authors work in the frequency range and propose an iterative IQML type algorithm to give an approximate solution with a maximum probability and an explicit initialisation algorithm based on the ESPRIT algorithm. These algorithms do not require advance knowledge of the transmission filter, but do have the disadvantage that a Fourier transformation is necessary before processing.

SUMMARY OF THE INVENTION

[0028] The invention relates to a blind or partially blind process that can determine at least the characteristic space-time parameters of a propagation channel in a system comprising at least one sensor for reception of signals y(t), characterized in that it comprises at least one step in which the specular type structure of the channel is taken into account and a step for the joint determination of space-time parameters such as antenna vectors (a) and/or time vectors (τ) starting from second order statistics of the signals received on one or several sensors.

[0029] According to one embodiment, it comprises a step in which the received signal y(t) is oversampled, for example with a sampling period equal to T/p, where T is the symbol period.

[0030] According to another embodiment, the process comprises a reception step on at least two sensors and an oversampling step.

[0031] For example, the process according to the invention may be applied for standard links for equalization, positioning and spatial filtering purposes, or for monitoring the spectrum of a propagation channel for positioning purposes starting from one or several HF stations.

[0032] In particular, the invention has the following advantages::

[0033] there is no need to transmit a learning sequence that may reduce the effective transmission throughput, or to know the length of the global transmission channel,

[0034] it is tolerant to an overestimate of the order of the transmission channel.

BRIEF DESCRIPTION OF THE DRAWINGS

[0035] Other advantages and characteristics of the invention will become clear after reading the following description with reference to the single FIGURE given for illustrative purposes and in no way limitative, and that shows the schematic for a radio-communication receiver according to the invention.

DESCRIPTION OF THE PREFERRED EMBODIMENT

[0036] We will mention a few remainders, assumptions and definitions before going on to describe the steps in the process according to the invention.

Assumptions and Model

[0037] The Single Sensor Signal Model

[0038] The transmitted signal is in the form $\begin{matrix} {{x(t)} = {\sum\limits_{l \in Z}{{g\left( {t - {IT}} \right)}{s(I)}}}} & (3) \end{matrix}$

[0039] where g(t) is the transmission/reception filter and values in {s(I)} are information symbols that were sent at the symbol period T.

[0040] The system assumes that the carrier frequency and the symbol period are estimated in advance. The signal received in base band is written $\begin{matrix} {{y(t)} = {{\sum\limits_{l \in Z}{{h\left( {t - {IT}} \right)}{s(I)}}} + {w(t)}}} & (4) \end{matrix}$

[0041] where the values of {s(I)} are information symbols that were sent at the symbol period T, h(t) is the pulse response of the transmission channel, and w(t) is an additive noise. The received signal sampled at the symbol period follows the discrete model: $\begin{matrix} {{y(k)} = {{{y({kT})}{\sum\limits_{l \in Z}{{h\left( {k - I} \right)}{s(I)}}}} + {w(k)}}} & (5) \end{matrix}$

[0042] where h(I) =h(IT) (assuming that the sampling phase is equal to 0).

[0043] The Multichannel System

[0044]FIG. 1 represents a multichannel reception system comprising a number q of reception sensors and a means of oversampling the signal s(k) corresponding to path index k.

[0045] Obviously, without going outside the framework of the invention, the process can also apply to receivers comprising several sensors without any means of oversampling, or comprising a single sensor and a means of oversampling the received signal.

[0046] In the example embodiment given below, the device considered is a multichannel system combining spatial diversity and time diversity, i.e the signal is received on a network of q sensors Ci each having a response h_((i))(t) and it is then oversampled with respect to the symbol period T, at the rate T/p as shown in FIG. 1. Oversampling is done using an appropriate device. The global pulse response of the transmission channel and the multi-sensor observations vector are defined by the following q×1 column vectors:

h(t)=[h₍₁₎(t), . . . , h_((q))(t)]^(T)  (6)

y(t)=[y₍₁₎(t), . . . , y_((q))(t)]^(T)  (7)

[0047] The subscript indicates the sensor number and the superscript T represents the transpose of a matrix. Bold characters indicate a spatial dimension. The samples obtained by sampling at rate T/p are vectorized by collecting signals sampled in the same sampling phase within a symbol period. More precisely, a path is associated with each of the p different sampling phases at the symbol rate, thus creating a multipath channel with p outputs on each sensor. This gives a multipath channel with p.q outputs. The global pulse response of the transmission channel and the multipath observations vector are defined by the following column vectors p.q×1:

h (k)=[h ⁽¹⁾(kT) . . . h^((p))(kT)]^(T)  (8)

y (k)=[y ⁽¹⁾(kT) . . . y^((p))(kT)]^(T)  (9)

[0048] The superscript indicates the sampling phase,

h ^((i))(kT)=h(kT+(i−1 )T/p), y ^((i))(kT)=y(kT+(i−1 )T/p).

[0049] Assumptions

[0050] The process according to the invention is based on a number of assumptions, and particularly the following.

[0051] Symbols Source

[0052] H 1—For example, process {s(k)} is a complex white noise that may also be circular at the second order of unit variance,

E[s(k)]=0, E[s(k)s(j)^(H)]=δ(k−j), E[s(k)s(j)]=0  (10)

[0053] Noise

[0054] H 2—Noise w(k) is a Gaussian, circular, white process stationary in space and time with variance σ²,

E[w (k) w (k)^(H)]=σ² Ipq  (11 )

[0055] where Ipq is the identity matrix

[0056] Transmission/Reception Filter

[0057] H 3—The transmission/reception filter g(t) has a finite support, g(t)=0 for t ∉[0, LgT[ where Lg corresponds to the filter length and T to the sampling period.

[0058] H 4—The transmission/reception filter g(t)⇄G(f) is approximately as follows for a limited band, with band B_(g)

G(f)≈0∀f∉[−B _(g) ,B _(g)]  (12)

[0059] and G(f) does not cancel out within a given band β,

G(f)≠0∀f∈[−B _(g) ,B _(g)]  (13)

[0060] Propagation Channel

[0061] H 5—The signal is a narrow band for the sensor network, i.e. it is assumed that the propagation time for the signal to pass from one sensor to the next is very much less than the inverse of the signal band.

[0062] H 6—The channel is constant over an observation interval. The Doppler shift and carrier residues are assumed to be negligible.

[0063] H 7—The time difference between the first and last path is finite, and it has an upper limit: Δτ_(max).

[0064] where d is the number of paths and τ_(k) is the delay and a_(k) is the vector of q×1 dimension antennas associated with the kth path, the channel response being expressed as follows. $\begin{matrix} {{h(t)} = {\sum\limits_{k = 1}^{d}\quad {a_{k}{g\left( {t - \tau_{k}} \right)}}}} & (14) \end{matrix}$

[0065] By sampling at T/p, $\begin{matrix} {{h_{\frac{T}{p}}(z)} = {{\sum\limits_{k = {- \infty}}^{\propto}\quad {{h\left( {{kT}/p} \right)}z^{- k}}} = {\sum\limits_{k = 1}^{d}\quad {a_{k}{g_{\frac{T}{p}}\left( {\tau_{k};z} \right)}}}}} & (15) \end{matrix}$

[0066] where $\begin{matrix} {{g_{\frac{T}{p}}\left( {\tau;z} \right)}\underset{\_}{\underset{\_}{\Delta}}{\sum\limits_{n}{{g\left( {{n\frac{T}{p}} - \tau} \right)}z^{- n}}}} & (16) \end{matrix}$

[0067] is the transform into z of the transmission/reception filter shifted by τ and sampled at T/p.

[0068] Furthermore, h(z) is the response in z to the symbol rate of the combined system, $\begin{matrix} {{\underset{\_}{h}(z)} = {\sum\limits_{k = {- \infty}}^{\infty}\quad {{\underset{\_}{h}({kT})}z^{- k}}}} & (17) \end{matrix}$

[0069] The received signal follows the equivalent single source multi-output discrete model:

y (k)=[h(z)]s(k)+ w (k)  (18)

[0070] it is interesting to note that $\begin{matrix} {{h_{\frac{T}{p}}(z)} = {\sum\limits_{i = 1}^{p}\quad {{h^{(i)}\left( z^{p} \right)}z^{- i}}}} & (19) \end{matrix}$

[0071] where h^((i))(z)=Σ_(k=−∞) ^(∞) h^((i))(k)Z^(−k) are the multi-phase components of the oversampled channel.

[0072] According to assumptions H3 and H7, the pulse response of the global multi-sensor transmission channel has a finite length. Therefore, the degree of the discrete responses h(z) and h_(T/p)(z) is finite. We note L=deg(h) i.e. the degree of at least one of the paths is equal to L, the degrees of the others may be lower,

h(z)= h (0)+ h (1)z ⁻¹ + . . . +h (L)z ^(−L)

[0073] Similarly, we denote L_(T/p)=deg(h_(T/p)). We have pL≦L_(T/p≦p(L+)1)−1. In order to simplify the presentation, we assume that

L _(T/p)+1=p(L+1).

[0074] Furthermore, second order algorithms are based on the following diversity condition for the global transmission channel:

[0075] H 8 The polynomial vector h(z) is irreducible, i.e. these components do not have any common roots.

[0076] Some Notations and Tools

[0077] If {b⁽¹⁾(z), . . . , b^((r))(z)} are r scalar polynomials, b(z)=[b⁽¹⁾(z), . . . , b^((r))(z)]^(T) is a polynomial vector (a vector for which the coordinates are polynomials) with dimension r. The maximum degree of the polynomials is called the order or the degree of the vector deg(b(z)) {b⁽¹⁾(z), . . . , b^((r))(z)}. If L_(b) is the degree of b(z), then $\begin{matrix} {{b(z)} = {\sum\limits_{k = 0}^{L\quad b}{{b(k)}z^{- k}}}} & (20) \end{matrix}$

[0078] where b(k)=[b⁽¹⁾(k) , . . . , b^((r))(k)]^(T). The vector associated with b(z), i.e. containing all its coefficients, is denoted by an arrow,

{right arrow over (b)}=[b(0)^(T) . . . b(L _(b))^(T)]^(T)  (21)

[0079] with dimension r(L_(b)+1)×1. Therefore, in particular {tilde over (h)} corresponds to the dimension vector q.p(L+1)×1 associated with h(z) and h_(T/p)(z) i.e. containing all their coefficients, $\begin{matrix} {\overset{\rightarrow}{h} = \left\lbrack {{\underset{\_}{h}(0)}^{T}\ldots \quad {\underset{\_}{h}(L)}^{T}} \right\rbrack^{T}} & (22) \\ {\quad {= \left\lbrack {{h_{\frac{T}{p}}(0)}^{T}\ldots \quad {h_{\frac{T}{p}}\left( L_{\frac{T}{p}} \right)}^{T}} \right\rbrack^{T}}} & (23) \end{matrix}$

[0080] Furthermore, let K be an integer defining the number of multidimensional observations, _(k)(b) is the Sylvester matrix (i.e. Toeplitz per block) with dimension r(K+1)×(K+L_(b)+1) associated with the polynomial b(z), and defined by $\begin{matrix} {{\tau_{k}(b)} = \begin{bmatrix} {b(0)} & \ldots & {b\left( L_{b} \right)} & 0 & \ldots & 0 \\ 0 & {b(0)} & \quad & {b\left( L_{b} \right)} & ⋰ & \vdots \\ \vdots & ⋰ & ⋰ & \quad & ⋰ & 0 \\ 0 & \ldots & 0 & {b(0)} & \ldots & {b\left( L_{b} \right)} \end{bmatrix}} & (24) \end{matrix}$

[0081] Finally, let B(z) be a polynomial matrix with dimension r×D and degree L_(b),

B(z)=[b ₁(z), . . . , b _(D)(z)]

[0082] where b_(i)(z) is a polynomial vector with dimension r. We will use

B=[{right arrow over (b)} ₁ , . . , {right arrow over (b)} _(D)]

[0083] to denote the associated matrix with dimensions r(L_(b)+1)×D, and D_(K)(B) to denote the Sylvester block matrix with dimensions r(K+1)×(K+L_(b)+1)D defined by

D _(k)(B)=[T _(k)(b ₁), . . . , T _(k)(b _(D))]  (25)

[0084] λ_(min)(A) denotes the smallest eigenvalue of matrix A and vp_(min)(A) is the eigenvector associated with λ_(min)(A).

[0085] Process According to the Invention

[0086] The process according to the invention is based particularly on taking account of the specular type channel structure to determine the specific parameters of a signal propagation or transmission channel, particularly in a communication system like that shown in FIG. 1. For example, the parameters determined jointly may be the time vector (τ) of delay vectors (τ_(k)), and the antenna vector (a) of vectors (a_(k)).

[0087] A first alternative embodiment of the process or the “a priori process” is particularly suitable when the transmission/reception filter is known.

[0088] A second alternative embodiment of the process or “no a priori process” is more suitable for the case in which the characteristics of the transmission/reception filter are not known.

[0089] A Priori Process

[0090] The process assumes that the transmission filter g(t) is known. The various steps in the a priori process or algorithm according to the invention are based on the fact that equation (15) is written in “vectorial” form as follows:

{right arrow over (h)}=G _(L,d)(τ)a  (26)

[0091] {right arrow over (h)} is the vector with dimension q.p.(L+1) containing all coefficients of the response h_(T/p)(z), a is the vector with dimension q.d containing all antenna vectors a=[a_(l) ^(T) . . . a_(d) ^(T)]^(T) and G_(L,d)(τ) is a matrix with dimension q.p(L+1)×q.d containing delayed versions sampled at T/p of the transmission filter: $\begin{matrix} {{G_{L,d}(\tau)} = {\begin{pmatrix} {g\left( {0 - \tau_{l}} \right)} & \ldots & {g\left( {0 - \tau_{d}} \right)} \\ {g\left( {\frac{T}{p} - \tau_{l}} \right)} & \ldots & {g\left( {\frac{T}{p} - \tau_{d}} \right)} \\ \vdots & \quad & \vdots \\ {{{g\left( {L + 1} \right)}T} - \frac{T}{p} - \tau_{l}} & \ldots & {{{g\left( {L + 1} \right)}T} - \frac{T}{p} - \tau_{d}} \end{pmatrix} \otimes I_{q}}} & (27) \end{matrix}$

[0092] I_(q) is the identity matrix with dimension q. We will use τ to denote the vector with dimension d containing all delays τ=[τ_(l), . . . τ_(d)]

[0093] For example, the different steps in the process could be as follows:

[0094] 1. Choose the length of the global propagation channel taking account of transmission and reception, {circumflex over (L)}≧L_(g)+Δτ_(max) and the value of the number of observations K≧{circumflex over (L)} where Δτ_(max) is the largest possible value of the relative delay between two paths.

[0095] 2. Calculate the sub-space criterion matrix Q_({circumflex over (L)})({circumflex over (R)}), for example as follows:

[0096] Calculate the empirical estimate of the covariance matrix: $\begin{matrix} {\hat{R} = {\frac{1}{N - K}{\sum\limits_{k = 0}^{N - K}{{\overset{\rightarrow}{y\quad}}_{K}(k){{\overset{\rightarrow}{y}}_{K}(k)}^{H}}}}} & (28) \end{matrix}$

[0097]  where

{right arrow over (y)} _(K)(k)=[y(0)^(T) y(T/p)^(T) . . . y(KT−T/p)^(T)]^(T)  (29)

=] y (0)^(T) . . . y (K)^(T)]_(pg(K−1)) ^(T)  (30)

[0098]  and let N-K be the number of independent observations.

[0099] Build the matrix Ĝ_({circumflex over (L)}) for example using the eigenvectors associated with the pq(K+1)−(K+{circumflex over (L)}+1) smallest eigenvalues of {circumflex over (R)}. Ĝ_({circumflex over (L)}) can also be obtained from the breakdown of the data matrix Y=⁶⁶ [{right arrow over (y)}(K) . . . {right arrow over (y)}(N)].) into eigenelements. Then form the projection matrix {circumflex over (Π)}_({circumflex over (L)})=Ĝ_({circumflex over (L)})Ĝ_({circumflex over (L)}) ^(H)

[0100] Form the sub-space criterion matrix Q_({circumflex over (L)})({circumflex over (R)})=D_({circumflex over (L)})({circumflex over (Π)}_({circumflex over (L)}))D_({circumflex over (L)})({circumflex over (Π)}_({circumflex over (L)}))^(H)

[0101] 3. Estimate the number of paths, for example {circumflex over (d)}, by using the method described in the “Detection of signals by information theory criteria” reference by M. Wax and T. Kailath, IEEE Trans.on Acoust. and Sig. Proc., 33(2): 387-392, April 1985.

[0102]4. Estimate the delays $\begin{matrix} {{\hat{\tau} = {\arg \quad {\min\limits_{\tau}{J_{\hat{L},\hat{d}}(\tau)}}}}{where}} & \quad \\ {{J_{\hat{L},\hat{d}}(\tau)} = \frac{\lambda_{\min}\left( {{G_{\hat{L},\hat{d}}(\tau)}^{H}{Q_{\hat{L}}\left( \hat{R} \right)}{G_{\hat{L},\hat{d}}(\tau)}} \right)}{\lambda_{\min}\left( {{G_{\hat{L},\hat{d}}(\tau)}^{H}{G_{\hat{L},\hat{d}}(\tau)}} \right)}} & (31) \end{matrix}$

[0103] This is done by applying the iterative process described below:

[0104] Let d=1. Obtain an estimate {circumflex over (τ)}₁ of τ₀₁ by minimizing {haeck over (J)}_({circumflex over (L)},{circumflex over (d)})(τ₁)

[0105] Let d=2. Obtain and estimate {circumflex over (τ)}₂ of τ₀₂ by minimizing {haeck over (J)}_({circumflex over (L)},{circumflex over (d)})([τ₁,τ₂]) as a function of τ₂ and keeping τ₁ equal to the estimate {circumflex over (τ)}₁ obtained in the first step. Then, obtain a new estimate of [τ₀₁, τ₀₂] using a multidimensional minimization of {haeck over (J)}_({circumflex over (L)},{circumflex over (d)})([τ₁,τ₂]) and using the values [{circumflex over (τ)}₁, {circumflex over (τ)}₂] that were obtained above as initial values.

[0106] Iterate this process until d={circumflex over (d)},for all possible paths in order to obtain the delay vector.

[0107] 5. Estimate the value of the antenna vector by

â=vp _(min)(G _({circumflex over (L)},{circumflex over (d)})(τ)^(H) Q _({circumflex over (L)})({circumflex over (R)})G_({circumflex over (L)},{circumflex over (d)})({circumflex over (τ)}))

[0108] 6. Create the estimate of the pulse response: {right arrow over (ĥ)}=G_({circumflex over (L)},{circumflex over (d)})({circumflex over (τ)})â

[0109] No A Priori Process

[0110] The second alternative of the process corresponds to a parameter estimating algorithm that is entirely or mostly blind. As in the first alternative embodiment, the associated algorithm takes account of the specular nature of the propagation channel in order to determine its parameters, and particularly the antenna vector and the characteristics time vector. Unlike the first variant, it does not require advanced knowledge of the transmission filter. It simply assumes that the transmission filter has a limited band and that its band is known approximately.

[0111] For example, the various steps in the process or algorithm are as follows:

[0112] 1. Estimate {circumflex over (L)}g, the length of the transmission filter, and choose {circumflex over (L)}≧{circumflex over (L)}_(g)+Δτ_(max) and K≧{circumflex over (L)}

[0113] 2. Apply the sub-space method described in item 2 of the a priori process:

[0114] Estimate the covariance matrix {circumflex over (R)}, for example using the steps described above corresponding to equation (Eq. 28).

[0115] Calculate the projection matrix on the noise space {circumflex over (Π)}_({circumflex over (L)}) starting from the eigenvectors associated with the pq(K+1)−(K+{circumflex over (L)}+1) null eigenvalues of the matrix {circumflex over (R)}.

[0116] Form the matrix Q_({circumflex over (L)})({circumflex over (R)})=D_({circumflex over (L)})({circumflex over (Π)}_({circumflex over (L)}))D_({circumflex over (L)})({circumflex over (Π)}_({circumflex over (L)}))^(H)

[0117] Obtain {right arrow over (ĥ)} the eigenvector associated with the smallest eigenvalue of the matrix Q_({circumflex over (L)})({circumflex over (R)}) and form ${\hat{h}}_{\frac{T}{p}}(z)$

[0118] 3. Form the new parametric criterion:

[0119] Choose the value of the channel length ${R \geq {\hat{L}}_{\frac{T}{p}}} = {{p\left( {\hat{L} + 1} \right)} - 1}$

[0120] and form the matrix $\tau_{R}\left( {\hat{h}}_{\frac{T}{p}} \right)$

[0121] Calculate the matrix ${\hat{\Omega}}_{{\hat{L}}_{\frac{T}{p}}}$

[0122]  containing eigenvectors associated with the ${q\left( {R + 1} \right)} - {\left( {R + {\hat{L}}_{\frac{T}{p}} + 1} \right)\quad {smallest}\quad {eigenvalues}\quad {of}\quad {\tau_{R}\left( {\hat{h}}_{\frac{T}{p}} \right)}^{H}}$ $\text{-}{Form}\quad {the}\quad {matrix}\quad D_{{\hat{L}}_{\frac{T}{p}}}\quad \left( {\hat{\Omega}}_{{\hat{L}}_{\frac{T}{p}}} \right)$

[0123] 4. Estimate the number of paths {circumflex over (d)}, for example using the method referenced above for step 3 in the first alternative embodiment.

[0124] 5. Determine the minimum value of the band of the transmission filter: β, usually β=1/T.

[0125] 6. Choose {tilde over (v)}(t), a continuous filter with band limited to the β band. Form the filter v(t), $\begin{matrix} \left\{ \begin{matrix} {{v(t)} = {\overset{\sim}{v}(t)}} & {0 \leq t \leq {Lv} \leq {\hat{L}g}} \\ {\quad {{v(t)} = 0}} & {elsewhere} \end{matrix} \right. & (32) \end{matrix}$

[0126] 7. Estimate the delays $\begin{matrix} {{\hat{\tau} = {\arg \quad {\min\limits_{\tau}{I_{\hat{L},\hat{d}}(\tau)}}}}{where}} & \quad \\ {{I_{\hat{L},\hat{d}}(\tau)} = \frac{\lambda_{\min}\left( {{V_{\hat{L},\hat{d}}(\tau)}^{H}{D_{\hat{L}\frac{T}{p}}\left( {\hat{\Omega}}_{\hat{L}\frac{T}{p}} \right)}{D_{\hat{L}\frac{T}{p}}\left( {\hat{\Omega}}_{\hat{L}\frac{T}{p}} \right)}^{H}{V_{\hat{L},\hat{d}}(\tau)}} \right)}{\lambda_{\min}\left( {{V_{\hat{L},\hat{d}}(\tau)}^{H}{V_{\hat{L},\hat{d}}(\tau)}} \right)}} & (33) \end{matrix}$

[0127] where

[0128] using the iterative process proposed for the parametric subspace method. (The matrix V_({circumflex over (L)},{circumflex over (d)})(τ) is defined in the same way as the matrix G_({circumflex over (L)},{circumflex over (d)})(τ) but from the filter v(t).)

[0129] 8. Estimate antenna vectors: $\begin{matrix} {\hat{a} = {{vP}_{\min}\left( {{V_{\hat{L},\hat{d}}\left( \hat{\tau} \right)}^{H}{D_{\hat{L}\frac{T}{p}}\left( {\hat{\Omega}}_{\hat{L}\frac{T}{p}} \right)}{D_{\hat{L}\frac{T}{p}}\left( {\hat{\Omega}}_{\hat{L}\frac{T}{p}} \right)}^{H}{V_{\hat{L},\hat{d}}\left( \hat{\tau} \right)}} \right)}} & (34) \end{matrix}$

[0130] Possible Applications

[0131] The process according to the invention is applied, for example in the domains mentioned below for illustrative purposes and in no way limitative.

[0132] Cellular Networks

[0133] For cellular transmissions, the transmission standard is known. Therefore, the standard transmission filter is known and it is preferable to apply the a priori process using advance knowledge of the transmission/reception filter. The potential applications are as follows:

[0134] Equalization

[0135] Propagation acts as time convolution. Except for very low throughput communications (a few hundred bits per second), this time dispersion induced by propagation creates interference between symbols (IES). In order to best recover the transmitted symbols, the dispersive effect of the channel must be compensated by an equalization step like that described in the book entitled “Digital Communications”, written by J. G. Proakis and published by McGraw Hill editions, 1989. If the transmission/reception filter is known, the global response can be built up starting from knowledge of propagation channel parameters, and an equalization step can be applied. The advantage of this approach is that in general, by estimating propagation parameters rather than the global response, the number of parameters to be estimated is smaller so that it is usually possible to reduce the variance of the estimators. The identification quality and equalization performances can thus be improved significantly. Furthermore, some characteristic parameters of the propagation channel (arrival delays and angles) do not change very much from one frame to the next. Parametric modelling makes it more efficient to monitor variations of channel parameters and further improves the identification quality, for example such as described in the “Multi-channel MLSE equalizer with parametric FIR channel identification” reference by J. T. Chen and A. Paulraj, in VTC, Proc., pages 710-713, 1997.

[0136] Positioning

[0137] Positioning of the transmitter is a classical problem in military applications, and has recently become the subject of close attention for civil applications in mobile communications. Positioning of mobiles in a cellular network makes it possible to provide many services such as positioning of emergency calls, management of charging, detection of fraud, assistance with cellular planning, improvement in organizing the “handover” as described in “Position location using wireless communications on highways of the future” reference by T. S. Rappaport, J. H. Reed and B. D. Woerner, IEEE Commun. Mag., October 1996.

[0138] Several techniques can be used for positioning. The most classical is triangularization. In this case, positioning is done using two or three separate receivers (base stations) each estimating the angles and/or arrival times of the transmitted signal as described in the “Mobile Localization in a GSM Network ” reference by H. El Nahas, PhD thesis ENST, June 1999. This system has some disadvantages, which is why positioning algorithms from a single station were developed. These positioning techniques always require prior knowledge of propagation characteristics. For example, a positioning process is described in the reference entitled “Procédés de localisation spatio-temporel de radiomobiles en milieu urbain” (Space-time positioning processes for radiomobiles in urban environment) by M. Chenu-Tournier, A. Ferréol and J-J. Monot, Technical report, TCC, 1997.

[0139] Antenna Filtering—SDMA

[0140] Knowledge of spatial characteristics of the different paths may be used to focalise transmission in the main arrival direction and thus minimize the effect of multiple paths on receivers (uplink beamformer design, downlink transmission design).

[0141] Spectrum Monitoring

[0142] In the context of a spectrum radio-electrical analysis, the receiver has no prior knowledge about the transmitter. The reception system scans the spectrum, intercepts a signal transmitted by an unknown transmitter and analyses it to extract some information from it to be able to listen to the transmission or determine the position of the transmitter. In this context, it is unlikely that the transmission filter will be known and the no a priori process is the most suitable for estimating propagation channel parameters (τ ; a). In this case, since the transmission filter is not known, it is impossible to equalize the received signal, but knowledge of parameters (τ ; a) would make it possible to use the applications mentioned below.

[0143] Positioning

[0144] The main application is positioning. In HF, positioning with a single station conventionally uses an initial step of ionospheric forecasts. Knowing the angle of incidence and the electronic density profile (by ionospheric forecasting), a ray plotting method using Descartes law can be used to reconstitute the path of the wave received on the sensors network according to one of the following references:

[0145] “Comparison of the fixing accuracy of single-station location of long range transmitters, by H. C. Höring, IEEE Proceedings, 37(3): 173-176, June 1990.

[0146] “Ioniospheric modelling in support of single station location of long range transmitters by L. F. McNamara, Journal of Atmospheric and terrestrial Physics, 50(9): 781-795, 1988.

[0147] Knowledge of arrival times can also eliminate some ambiguities due to multi-skip.

[0148] Others

[0149] Spatial filtering is possible if antenna vectors are known. Knowledge of delays is a means of recombining propagation paths in phase. The use of one or both of the two known values may be a first step in implementing a signal analysis system. 

1. Blind or partially blind process to determine characteristics space-time parameters of a propagation channel in a system comprising at least one reception sensor receiving a signal y(t), characterized in that it comprises at least one step in which the specular type structure of the channel is used and a step for the joint determination of parameters such as antenna vectors (a) and/or time vectors (τ) starting from second order statistics of the received signals.
 2. Process according to claim 1, characterized in that it comprises a step in which the received signal is oversampled.
 3. Process according to claim 1, characterized in that it comprises a step in which the signals are received on at least two sensors and a step in which the received signal is oversampled.
 4. Process according to any one of claims 2 and 3, characterized in that the sampling period corresponds to T/p where T is the symbol period.
 5. Process according to any one of claims 1 to 4, characterized in that it comprises at least the following steps: choose the length of the global propagation channel {circumflex over (L)}>Lg+Δτ_(max) and the value of the number of observations K>{circumflex over (L)} where Δτ_(max) is the largest possible value of the relative delay between two paths determine the Q_({circumflex over (L)})({circumflex over (R)}) matrix of the sub-space criterion, estimate the number of paths {circumflex over (d)}, estimate delays $\hat{\tau} = {\arg \quad {\min\limits_{\tau}\quad {J_{\hat{L},\hat{d}}(\tau)}}}$ ${J_{\hat{L},\hat{d}}(\quad)} = \frac{\lambda_{\min}\left( {\left( {G_{\hat{L},\hat{d}}(\tau)} \right)^{H}{Q_{\hat{L}}\left( \hat{R} \right)}{G_{\hat{L},\hat{d}}(\tau)}} \right)}{\lambda_{\min}\left( {\left( {G_{\hat{L},\hat{d}}(\tau)} \right)^{H}{G_{\hat{L},\hat{d}}(\tau)}} \right)}$

estimate the value of the antenna vector by â=vp _(min)(G_({circumflex over (L)},{circumflex over (d)})(τ)^(H) Q _({circumflex over (L)})({circumflex over (R)})G_({circumflex over (L)},{circumflex over (d)})({circumflex over (τ)})) form the estimate of the pulse response: ĥ=G_({circumflex over (L)},{circumflex over (d)})({circumflex over (τ)})â
 6. Process according to one of claims 1 to 4, characterized in that it comprises at least the following steps: Estimate {circumflex over (L)}g the length of the transmission filter and choose {circumflex over (L)}≧{circumflex over (L)}g+Δτ_(max) and K≧{circumflex over (L)}. Apply the sub-space method described in item 2 of the a priori process: Estimate the covariance matrix {circumflex over (R)}. Calculate the projection matrix onto noise space {circumflex over (Π)}_({circumflex over (L)}) using the eigenvectors associated with the pq(K+1)−(K+{circumflex over (L)}+1) null eigenvalues of the matrix {circumflex over (R)}. Form the matrix Q_({circumflex over (L)})({circumflex over (R)})=D_({circumflex over (L)})({circumflex over (Π)}_({circumflex over (L)}))D_({circumflex over (L)})({circumflex over (Π)}_({circumflex over (L)}))^(H) Obtain the {right arrow over (h)} eigenvector associated with the smallest eigenvalue of the matrix Q_({circumflex over (L)})L ({circumflex over (R)}) and form ${\hat{h}}_{\frac{T}{p}}(z)$

Form the new parametric criterion: Choose the value of the channel length ${R \geq {\hat{L}}_{\frac{T}{P}}} = {{p\left( {\hat{L} + 1} \right)} - 1}$

And form the matrix $\left( {\hat{h}\frac{T}{p}} \right)$

Calculate the matrix ${\hat{\Omega}}_{\hat{L}\frac{T}{p}}$

containing the eigenvectors associated with the ${q\left( {R + 1} \right)} - \left( {R + {\hat{L}}_{\frac{T}{p}} + 1} \right)$

 smallest eigenvalues of τ_(R) Form the matrix $D_{{\hat{L}}_{\frac{T}{p}}}\left( {\hat{\Omega}}_{{\hat{L}}_{\frac{T}{p}}} \right)$

Estimate the number of paths {circumflex over (d)}, Determine a minimum value of the transmission filter band: B, Choose {tilde over (v)}(t), a continuous filter with a limited band B. Form the filter v(t), $\quad\left\{ \begin{matrix} {{v(t)} = {\overset{\sim}{v}(t)}} & {0 \leq t \leq {Lv} \leq {\hat{L}g}} \\ {{v(t)} = 0} & {elsewhere} \end{matrix} \right.$

Estimate the delays $\hat{\tau} = {\arg {\quad \quad}{\min\limits_{\tau}\quad {I_{\hat{L},\hat{d}}(\tau)}}}$

where $\quad {{I_{\hat{L},\hat{d}}(\tau)} = \frac{\lambda_{\min}\left( {{V_{\hat{L},\hat{d}}(\tau)}^{H}{D_{\hat{L}\frac{T}{p}}\left( {\hat{\Omega}}_{\hat{L}\frac{T}{p}} \right)}{D_{\hat{L}\frac{T}{p}}\left( {\hat{\Omega}}_{\hat{L}\frac{T}{p}} \right)}^{H}{V_{\hat{L},\hat{d}}(\tau)}} \right)}{\lambda_{\min}\left( {{V_{\hat{L},\hat{d}}(\tau)}^{H}{V_{\hat{L},\hat{d}}(\tau)}} \right)}}$

Estimate antenna vectors: $\hat{a} = {{vP}_{\min}\left( {{V_{\hat{L},\hat{d}}\left( \hat{\tau} \right)}^{H}{D_{\hat{L}\frac{T}{p}}\left( {\hat{\Omega}}_{\hat{L}\frac{T}{p}} \right)}{D_{\hat{L}\frac{T}{p}}\left( {\hat{\Omega}}_{\hat{L}\frac{T}{p}} \right)}^{H}{V_{\hat{L},\hat{d}}\left( \hat{\tau} \right)}} \right)}$

HV_({circumflex over (L)},{circumflex over (d)})({circumflex over (τ)}))
 7. Application of the process according to any one of claims 1 to 6 to monitor the spectrum of a propagation channel for positioning purposes from one or several HF stations.
 8. Application of the process according to any one of claims 1 to 6, for the standard communication links for equalization or positioning or spatial filtering. 